IDT MPC92432

DATA
SHEET
MPC92432
Freescale Semiconductor
Technical Data
Rev 2, 06/2005
1360 MHz Dual Output LVPECL
1360
MHz Dual Output LVPECL Clock
Clock
Synthesizer
Synthesizer
The MPC92432 is a 3.3 V compatible, PLL based clock synthesizer targeted
for high performance clock generation in mid-range to high-performance
telecom, networking, and computing applications. With output frequencies from
21.25 MHz to 1360 MHz and the support of two differential PECL output signals,
the device meets the needs of the most demanding clock applications.
MPC92432
MPC92432
1360 MHz LOW VOLTAGE
CLOCK SYNTHESIZER
Features
•
•
•
•
•
•
•
•
•
•
•
•
•
•
21.25 MHz to 1360 MHz synthesized clock output signal
Two differential, LVPECL-compatible high-frequency outputs
Output frequency programmable through 2-wire I2C bus or parallel interface
On-chip crystal oscillator for reference frequency generation
Alternative LVCMOS compatible reference clock input
Synchronous clock stop functionality for both outputs
LOCK indicator output (LVCMOS)
LVCMOS compatible control inputs
Fully integrated PLL
3.3-V power supply
48-lead LQFP
48-lead Pb-free package available
SiGe Technology
Ambient temperature range: –40°C to +85°C
FA SUFFIX(1)
48-LEAD LQFP PACKAGE
CASE 932-03
AE SUFFIX(2)
48-LEAD LQFP PACKAGE
Pb-FREE PACKAGE
CASE 932-03
Applications
• Programmable clock source for server, computing, and telecommunication systems
• Frequency margining
• Oscillator replacement
Functional Description
The MPC92432 is a programmable high-frequency clock source (clock synthesizer). The internal PLL generates a highfrequency output signal based on a low-frequency reference signal. The frequency of the output signal is programmable and can
be changed on the fly for frequency margining purpose.
The internal crystal oscillator uses the external quartz crystal as the basis of its frequency reference. Alternatively, a LVCMOS
compatible clock signal can be used as a PLL reference signal. The frequency of the internal crystal oscillator is divided by a
selectable divider and then multiplied by the PLL. The VCO within the PLL operates over a range of 1360 to 2720 MHz. Its output
is scaled by a divider that is configured by either the I2C or parallel interfaces. The crystal oscillator frequency fXTAL, the PLL predivider P, the feedback-divider M, and the PLL post-divider N determine the output frequency. The feedback path of the PLL is
internal.
The PLL post-divider N is configured through either the I2C or the parallel interfaces, and can provide one of six division ratios
(2, 4, 8, 16, 32, 64). This divider extends the performance of the part while providing a 50% duty cycle. The high-frequency outputs, QA and QB, are differential and are capable of driving a pair of transmission lines terminated 50 Ω to VCC – 2.0 V. The second
high-frequency output, QB, can be configured to run at either 1x or 1/2x of the clock frequency or the first output (QA). The positive
supply voltage for the internal PLL is separated from the power supply for the core logic and output drivers to minimize noise
induced jitter.
The configuration logic has two sections: I2C and parallel. The parallel interface uses the values at the M[9:0], NA[2:0], NB,
and P parallel inputs to configure the internal PLL dividers. The parallel programming interface has priority over the serial I2C
interface. The serial interface is I2C compatible and provides read and write access to the internal PLL configuration registers.
The lock state of the PLL is indicated by the LVCMOS-compatible LOCK output.
1. FA suffix: leaded terminations.
2. AE suffix: lead-free, EPP and RoHS-compliant.
IDT™ 1360 MHz Dual Output LVPECL Clock Synthesizer
MPC92432
© Freescale
Semiconductor,
Inc., has
2005.
All rights
reserved.
Freescale
Timing Solutions
Organization
been
acquired
by Integrated Device Technology, Inc
1
MPC92432
1360 MHz Dual Output LVPECL Clock Synthesizer
REF_CLK
XTAL1
XTAL2
fQA
÷NA
fVCO
PLL
÷P
fREF
XTAL
NETCOM
QA
fQB
÷NB
QB
REF_SEL
÷M
TEST_EN
SDA
ADR[1:0]
PLL
Configuration
Registers
PLOAD
I2C Control
SCL
LOCK
M[9:0]
NA[2:0]
NB
P
CLK_STOPx
BYPASS
MR
VCC
NB
VCC
QA
QA
GND
VCC
QB
QB
GND
LOCK
TEST_EN
Figure 1. MPC92432 — Generic Logic Diagram
36
35
34
33
32
31
30
29
28
27
26
25
GND
37
24
M9
NA2
38
23
M8
M7
39
22
NA0
40
21
M6
PLOAD
41
20
M5
VCC
42
19
GND
MR
43
18
M4
SDA
44
17
M3
SCL
45
16
M2
ADR1
46
15
M1
ADR0
47
14
M0
P
48
13
VCC
MPC92432
12
XTAL2
11
XTAL1
10
CLK_STOPB
9
CLK_STOPA
8
GND
7
REF_CLK
6
REF_SEL
5
VCC_PLL
4
VCC
3
GND
2
BYPASS
1
VCC
NA1
It is recommended to use an external
RC filter for the analog VCC_PLL supply
pin. Please see the application section
for details.
Figure 2. 48-Lead Package Pinout (Top View)
MPC92432
IDT™ 1360
MHz Dual Output LVPECL Clock Synthesizer
Freescale Timing Solutions Organization has been acquired by Integrated Device Technology, Inc
2
2
MPC92432
Advanced Clock Drivers Devices
Freescale Semiconductor
MPC92432
1360 MHz Dual Output LVPECL Clock Synthesizer
NETCOM
Table 1. Signal Configuration
Pin
I/O
Type
Function
XTAL1, XTAL2
Input
Analog
Crystal oscillator interface
REF_CLK
Input
LVCMOS
PLL external reference input
REF_SEL
Input
LVCMOS
Selects the reference clock input
QA
Output
Differential LVPECL
High frequency clock output
QB
Output
Differential LVPECL
High frequency clock output
LOCK
Output
LVCMOS
PLL lock indicator
M[9:0]
Input
LVCMOS
PLL feedback divider configuration
NA[2:0]
Input
LVCMOS
PLL post-divider configuration for output QA
NB
Input
LVCMOS
PLL post-divider configuration for output QB
P
Input
LVCMOS
PLL pre-divider configuration
P_LOAD
Input
LVCMOS
Selects the programming interface
SDA
I/O
LVCMOS
I2C data
SCL
Input
LVCMOS
I2C clock
ADR[1:0]
Input
LVCMOS
Selectable two bits of the I2C slave address
BYPASS
Input
LVCMOS
Selects the static circuit bypass mode
TEST_EN
Input
LVCMOS
Factory test mode enable. This input must be set to logic low level in all
applications of the device.
CLK_STOPx
Input
LVCMOS
Output Qx disable in logic low state
MR
Input
LVCMOS
Device master reset
GND
Supply
Ground
Negative power supply
VCC_PLL
Supply
VCC
Positive power supply for the PLL (analog power supply). It is recommended to
use an external RC filter for the analog power supply pin VCC_PLL.
VCC
Supply
VCC
Positive power supply for I/O and core
IDT™ 1360 MHz Dual Output LVPECL Clock Synthesizer
Advanced
Clock Drivers
Devices has been acquired by Integrated Device Technology, Inc
Freescale
Timing Solutions
Organization
Freescale Semiconductor
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MPC92432
MPC92432
3
MPC92432
1360 MHz Dual Output LVPECL Clock Synthesizer
NETCOM
Table 2. Function Table
Control
Default(1)
0
1
Inputs
REF_SEL
M[9:0]
NA[2:0]
1
01 1111
0100b(2)
Selects REF_CLK input as PLL reference clock
Selects the XTAL interface as PLL reference clock
PLL feedback divider (10-bit) parallel programming interface
010
PLL post-divider parallel programming interface. See Table 9
NB
0
PLL post-divider parallel programming interface. See Table 10
P
1
PLL pre-divider parallel programming interface. See Table 8
PLOAD
0
Selects the parallel programming interface. The
Selects the serial (I2C) programming interface. The
internal PLL divider settings (M, NA, NB and P) are internal PLL divider settings (M, NA, NB and P) are
equal to the setting of the hardware pins. Leaving
set and read through the serial interface.
the M, NA, NB and P pins open (floating) results in a
default PLL configuration with fOUT = 250 MHz. See
application/programming section.
ADR[1:0]
00
Address bit = 0
SDA, SCL
Address bit = 1
See Programming the MPC92432
BYPASS
1
PLL function bypassed
fQA = fREF ÷ NA and
fQB = fREF÷ (NA · NB)
PLL function enabled
fQA = (fREF ÷ P) · M ÷ NA and
fQB = (fREF ÷ P) · M ÷ (NA · NB)
TEST_EN
0
Application mode. Test mode disabled.
Factory test mode is enabled
CLK_STOPx
1
Output Qx is disabled in logic low state.
Synchronous disable is only guaranteed if NB = 0.
Output Qx is synchronously enabled
MR
The device is reset. The output frequency is zero
The PLL attempts to lock to the reference signal.
and the outputs are asynchronously forced to logic The tLOCK specification applies.
low state.
After releasing reset (upon the rising edge of MR
and independent on the state of PLOAD), the
MPC92432 reads the parallel interface (M, NA, NB
and P) to acquire a valid startup frequency
configuration. See application/programming section.
Outputs
LOCK
PLL is not locked
PLL is frequency locked
1. Default states are set by internal input pull-up or pull-down resistors of 75 kΩ.
2. If fREF = 16 MHz, the default configuration will result in a output frequency of 250 MHz.
MPC92432
IDT™ 1360
MHz Dual Output LVPECL Clock Synthesizer
Freescale Timing Solutions Organization has been acquired by Integrated Device Technology, Inc
4
4
MPC92432
Advanced Clock Drivers Devices
Freescale Semiconductor
MPC92432
1360 MHz Dual Output LVPECL Clock Synthesizer
NETCOM
Table 3. General Specifications
Symbol
Characteristics
Min
Typ
Max
Output Termination Voltage
MM
ESD Protection (Machine Model)
200
V
HBM
ESD Protection (Human Body Model)
2000
V
200
LU
Latch-Up Immunity
CIN
Input Capacitance
θJA
LQFP 48 Thermal Resistance Junction to Ambient
JESD 51-3, single layer test board
LQFP 48 Thermal Resistance Junction to Case
Condition
V
mA
4.0
JESD 51-6, 2S2P multilayer test board
θJC
VCC – 2
Unit
VTT
pF
Inputs
69
64
°C/W Natural convection
°C/W 200 ft/min
53
50
°C/W Natural convection
°C/W 200 ft/min
TBD
TBD
°C/W MIL-SPEC 883E
Method 1012.1
Min
Max
Unit
Table 4. Absolute Maximum Ratings(1)
Symbol
VCC
VIN
VOUT
IIN
IOUT
TS
Characteristics
Supply Voltage
–0.3
3.9
V
(2)
–0.3
VCC + 0.3
V
DC Output Voltage
–0.3
VCC + 0.3
V
±20
mA
±50
mA
125
°C
DC Input Voltage
DC Input Current
DC Output Current
Storage Temperature
–65
Condition
1. Absolute maximum continuous ratings are those maximum values beyond which damage to the device may occur. Exposure to these
conditions or conditions beyond those indicated may adversely affect device reliability. Functional operation at absolute-maximum-rated
conditions is not implied.
2. All input pins including SDA and SCL pins.
IDT™ 1360 MHz Dual Output LVPECL Clock Synthesizer
Advanced
Clock Drivers
Devices has been acquired by Integrated Device Technology, Inc
Freescale
Timing Solutions
Organization
Freescale Semiconductor
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MPC92432
MPC92432
5
MPC92432
1360 MHz Dual Output LVPECL Clock Synthesizer
NETCOM
Table 5. DC Characteristics (VCC = 3.3 V ± 5%, TJ = –40°C to +85°C)
Symbol
Characteristics
Min
Typ
Max
Unit
Condition
LVCMOS Control Inputs (M[9:0], N[2:0], ADDR[1:0], NB, P, CLK_STOPx, BYPASS, MR, REF_SEL, TEST_EN, PLOAD)
VIH
Input High Voltage
VIL
Input Low Voltage
IIN
2.0
(1)
Input Current
VCC + 0.3
V
LVCMOS
0.8
V
LVCMOS
±200
µA
VIN = VCC or GND
VCC + 0.3
V
LVCMOS
LVCMOS
I2C Inputs (SCL, SDA)
VIH
Input High Voltage
VIL
Input Low Voltage
0.8
V
IIN
Input Current
±10
µA
2.0
LVCMOS Output (LOCK)
VOH
Output High Voltage
VOL
Output Low Voltage
2.4
V
IOH = –4 mA
0.4
V
IOL = 4 mA
0.4
V
IOL = 4 mA
I2C Open Drain Output (SDA)
VOL
Input Low Voltage
Differential Clock Output QA, QB
(2)
VOH
Output High Voltage
VCC–1.02
VCC–0.74
V
LVPECL
VOL
Output Low Voltage
VCC–1.95
VCC–1.60
V
LVPECL
1.0
V
Maximum PLL Supply Current
10
mA
VCC_PLL Pins
Maximum Supply Current
150
mA
All VCC Pins
VO(P-P)
Output Peak-to-Peak Voltage
0.5
0.6
Supply Current
ICC_PLL
ICC
1. Inputs have pull-down resistors affecting the input current.
2. Outputs terminated 50 Ω to VTT = VCC–2 V.
MPC92432
IDT™ 1360
MHz Dual Output LVPECL Clock Synthesizer
Freescale Timing Solutions Organization has been acquired by Integrated Device Technology, Inc
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MPC92432
Advanced Clock Drivers Devices
Freescale Semiconductor
MPC92432
1360 MHz Dual Output LVPECL Clock Synthesizer
NETCOM
Table 6. AC Characteristics (VCC = 3.3 V ± 5%, TJ = –40°C to +85°C)(1)
Symbol
Characteristics
Min
Typ
Max
Unit
16
fXTAL
Crystal Interface Frequency Range
15
20
MHz
fREF
FREF_EXT Reference Frequency Range
15
20
MHz
fVCO
VCO Frequency Range(2)
1360
2720
MHz
680
340
170
85
42.5
21.25
1360
680
340
170
85
42.5
MHz
MHz
MHz
MHz
MHz
MHz
0.4
MHz
(3)
fMAX
Output Frequency
fSCL
Serial Interface (I2C) Clock Frequency
0
Minimum Pulse Width (P_LOAD)
50
tP,MIN
DC
tSK(O)
N = ÷2
N = ÷4
N = ÷8
N = ÷16
N = ÷32
N = ÷64
Output Duty Cycle
45
Output-to-Output Skew
ns
50
55
%
38
96
ps
ps
0.05
0.3
ns
250
ns
NB = 0 (fQA = fQB)
NB = 1 (fQA = 2 · fQB)
tr, tf
Output Rise/Fall Time (QA, QB)
tr, tf
Output Rise/Fall Time (SDA)
Condition
20% to 80%
CL = 400 pF
tP_EN
Output Enable Time (CLKSTOPx to QA, QB)
0
2 · TQx
TQx = Output period
tP_DIS
Output Disable Time (CLKSTOPx to QA, QB)
0
1.5 · TQx
TQx = Output period
tJIT(CC)
Cycle-to-Cycle Jitter (RMS 1σ)
(4)
tJIT(PER) Period Jitter (RMS 1σ)(5)
BW
tLOCK
PLL Closed Loop Bandwidth(6)
N = ÷2, ÷4, ÷8
N = ÷16
N = ÷32
N = ÷64
N = ÷128
15
37
32
50
85
ps
ps
ps
ps
ps
N = ÷2, ÷4
N = ÷8
N = ÷16
N = ÷32
N = ÷64
N = ÷128
10
13
24
34
60
85
ps
ps
ps
ps
ps
ps
P=2
P=4
250 – 700
125 – 400
Maximum PLL Lock Time
kHz
kHz
10
ms
1. AC characteristics apply for parallel output termination of 50 Ω to VTT.
2. The input frequency fXTAL, the PLL divider M and P must match the VCO frequency range: fVCO = fXTAL · M ÷ P. The feedback divider M is
limited to 170 <= M <= 340 (for P = 2) and 340 <= M <= 680 (for P = 4) for stable PLL operation.
3. Output frequency for QA, QB if NB = 0. With NB = 1 the QB output frequency is half of the QA output frequency.
4. Maximum cycle jitter measured at the lowest VCO frequency. Figure 8 shows the cycle jitter vs. frequency characteristics.
5. Maximum cycle period measured at the lowest VCO frequency. Figure 9 shows the period jitter vs. frequency characteristics.
6. –3 dB point of PLL transfer characteristics.
IDT™ 1360 MHz Dual Output LVPECL Clock Synthesizer
Advanced
Clock Drivers
Devices has been acquired by Integrated Device Technology, Inc
Freescale
Timing Solutions
Organization
Freescale Semiconductor
7
MPC92432
MPC92432
7
MPC92432
1360 MHz Dual Output LVPECL Clock Synthesizer
NETCOM
APPLICATION INFORMATION
Output Frequency Configuration
The MPC92432 is a programmable frequency source
(synthesizer) and supports an output frequency range of
21.25 – 1360 MHz. The output frequency fOUT is a function of
the reference frequency fREF and the three internal PLL
dividers P, M, and N. fOUT can be represented by this formula:
fOUT = (fREF ÷ P) · M ÷ (NA, B)
(1)
The M, N and P dividers require a configuration by the user
to achieve the desired output frequency. The output divider,
NA, determines the achievable output frequency range (see
Table 7). The PLL feedback-divider M is the frequency
multiplication factor and the main variable for frequency
synthesis. For a given reference frequency fREF, the PLL
feedback-divider M must be configured to match the
specified VCO frequency range in order to achieve a valid
PLL configuration:
fVCO = (fREF ÷ P) · M and
(2)
1360 ≤ fVCO ≤ 2720
(3)
The output frequency may be changed at any time by
changing the value of the PLL feedback divider M. The
smallest possible output frequency change is the synthesizer
granularity G (difference in fOUT when incrementing or
decrementing M). At a given reference frequency, G is a
function of the PLL pre-divider P and post-divider N:
G = fREF ÷ (P · NA,B)
(4)
The NB divider configuration determines if the output QB
generates a 1:1 or 2:1 frequency copy of the QA output signal.
The purpose of the PLL pre-divider P is to situated the PLL
into the specified VCO frequency range fVCO (in combination
with M). For a given output frequency, P = 4 results in a
smaller output frequency granularity G, P = 2 results a larger
output frequency granularity G and also increases the PLL
bandwidth compared to the P = 2 setting.
The following example illustrates the output frequency
range of the MPC92432 using a 16-MHz reference
frequency.
Table 7. Frequency Ranges (fREF = 16 MHz)
fOUT (QA) [MHz]
680 – 1360
340 – 680
170 – 340
NA
NA = 2
NA = 4
NA = 8
85 – 170
NA = 16
42.5 – 85
NA = 32
21.25 – 42.5
NA = 64
Example Output Frequency Configuration
If a reference frequency of 16 MHz is available, an output
frequency at QA of 250 MHz and a small frequency
granularity is desired, the following steps would be taken to
identify the appropriate P, M, and N configuration:
1.
Use Table 7 to select the output divider, NA, that
matches the desired output frequency or frequency
range. According to Table 7, a target output frequency
of 250 MHz falls in the fOUT range of 170 to 340 MHz
and requires to set NA = 8.
2.
Calculate the VCO frequency fVCO = fOUT · NA, which is
2000 MHz in this example.
3.
Determine the PLL feedback divider: M = fVCO ÷ P.
The smallest possible output granularity in this example
calculation is 500 kHz (set P = 4). M calculates to a
value of 2000 ÷ 4 = 500.
4.
Configure the MPC92432 with the obtained settings:
M[9:0] = 0111110100b (binary number for M=500)
5.
NA[2:0] = 010
(÷8 divider, see Table 9)
P=1
(÷4 divider, see Table 8)
NB = 0
(fOUT, QB = fOUT, QA)
Use either parallel or serial interface to apply the
setting. The I2C configuration byte for this examples
are:
PLL_H=01010010b and PLL_L=11110100b.
See Table 14 and Table 15 for register maps.
PLL Divider Configuration
Table 8. Pre-PLL Divider P
P
Value
0
fREF ÷ 2
1
fREF ÷ 4
Table 9. Post-PLL Divider NA
M
P
G [MHz]
NA0
NA1
NA2
fOUT (QA)
170 – 340
2
4
0
0
0
fVCO ÷ 2
340 – 680
4
2
0
0
1
fVCO ÷ 4
170 – 340
2
2
0
1
0
fVCO ÷ 8
340 – 680
4
1
0
1
1
fVCO ÷ 16
170 – 340
2
1
1
0
0
fVCO ÷ 32
340 – 680
4
0.5
1
0
1
170 – 340
2
0.5
fVCO ÷ 64
340 – 680
4
0.25
Table 10. Post-PLL Divider NB
170 – 340
2
0.25
340 – 680
4
0.125
0
fOUT, QB = fOUT, QA
170 – 340
2
0.125
1
fOUT, QB = fOUT, QA ÷ 2
340 – 680
4
0.0625
NB
MPC92432
IDT™ 1360
MHz Dual Output LVPECL Clock Synthesizer
Freescale Timing Solutions Organization has been acquired by Integrated Device Technology, Inc
8
8
Value
MPC92432
Advanced Clock Drivers Devices
Freescale Semiconductor
MPC92432
1360 MHz Dual Output LVPECL Clock Synthesizer
NETCOM
Programming the MPC92432
The MPC92432 has a parallel and a serial configuration
interface. The purpose of the parallel interface is to directly
configure the PLL dividers through hardware pins without the
overhead of a serial protocol. At device startup, the device
always obtains an initial PLL frequency configuration through
the parallel interface. The parallel interface does not support
reading the PLL configuration.
The serial interface is I2C compatible. It allows reading and
writing devices settings by accessing internal device
registers. The serial interface is designed for host-controller
access to the synthesizer frequency settings for instance in
frequency-margining applications.
Using the Parallel Interface
The parallel interface supports write-access to the PLL
frequency setting directly through 15 configuration pins (P,
M[9:0], NA[2:0], and NB). The parallel interface must be
enabled by setting PLOAD to logic low level. During
PLOAD = 0, any change of the logical state of the P, M[9:0],
NA[2:0], and NB pins will immediately affect the internal PLL
divider settings, resulting in a change of the internal VCOfrequency and the output frequency. The parallel interface
mode disables the I2C write-access to the internal registers;
however, I2C read-access to the internal configuration
registers is enabled.
Upon startup, when the device reset signal is released
(rising edge of the MR signal), the device reads its startup
configuration through the parallel interface and independent
on the state of PLOAD. It is recommended to provide a valid
PLL configuration for startup. If the parallel interface pins are
left open, a default PLL configuration will be loaded. After the
low-to-high transition of PLOAD, the configuration pins have
no more effect and the configuration registers are made
accessible through the serial interface.
Table 11. PLL Feedback-Divider Configuration (M)
Feedback
Divider M
Pin
Default
9
8
7
6
5
4
3
2
1
M8
M7
M6
M5
M4
M3
M2
M1
M0
0
1
1
1
1
1
0
1
0
0
Pin
Default
1
0
NA2
NA1
NA0
0
1
1
N
Configuration Latches
M
LOAD/GET
PLL_L (R/W) PLL_H (R/W)
0x00
0x01
CMD (W)
0xF0
I2C Registers
I2C Access
Figure 3 illustrates the synthesizer register set. PLL_L and
PLL_H store a PLL configuration and are fully accessible
(Read/Write) by the I2C bus. CMD (Write only) accepts
commands (LOAD, GET, INC, DEC) to update registers and
for direct PLL frequency changes.
Set the synthesizer frequency:
Post-D.
NB
NB
Pre-D.
P
P
Pin
NB
Pin
P
0
Default
1
Default
Synthesizer – PLL
P
Figure 3. I2C Mode Register Set
M9
2
Programming Model and Register Set
The synthesizer contains two fully accessible configuration
registers (PLL_L and PLL_H) and a write-only command
register (CMD). Programming the synthesizer frequency
through the I2C interface requires two steps: 1) writing a valid
PLL configuration to the configuration registers and 2)
loading the registers into the PLL by an I2C command. The
PLL frequency is affected as a result of the second step.
This two-step procedure can be performed by a single I2C
transaction or by multiple, independent I2C transactions. An
alternative way to achieve small PLL frequency changes is to
use the increment or decrement commands of the
synthesizer, which have an immediate effect on the PLL
frequency.
0
Table 12. PLL Pre/Post-Divider Configuration (N, P)
Post-D.
NA
PLOAD = 0 disables the I2C-write-access to the configuration registers and any data written into the register is ignored.
However, the MPC92432 is still visible at the I2C interface
and I2C transfers are acknowledged by the device. Read-access to the internal registers during PLOAD = 0 (parallel programming mode) is supported.
Note that the device automatically obtains a configuration
using the parallel interface upon the release of the device
reset (rising edge of MR) and independent on the state of
PLOAD. Changing the state of the PLOAD input is not
supported when the device performs any transactions on the
I2C interface.
Using the I2C Interface
PLOAD = 1 enables the programming and monitoring of
the internal registers through the I2C interface. Device
register access (write and read) is possible through the 2-wire
interface using SDA (configuration data) and SCL
(configuration clock) signals. The MPC92432 acts as a slave
device at the I2C bus. For further information on I2C it is
recommended to refer to the I2C bus specification
(version 2.1).
1) Write the PLL_L and PLL_H registers with a new
configuration (see Table 14 and Table 15 for register
maps)
2) Write the LOAD command to update the PLL dividers
by the current PLL_L, PLL_H content.
Read the synthesizer frequency:
1) Write the GET commands to update the PLL_L,
PLL_H registers by the PLL divider setting
2) Read the PLL_L, PLL_H registers through I2C
Change the synthesizer frequency in small steps:
1) Write the INC or DEC command to change the PLL
frequency immediately. Repeat at any time if desired.
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MPC92432
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MPC92432
1360 MHz Dual Output LVPECL Clock Synthesizer
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LOAD and GET are inverse command to each other.
LOAD updates the PLL dividers and GET updates the
configuration registers. A fast and convenient way to change
the PLL frequency is to use the INC (increment M) and DEC
(decrement M) commands of the synthesizer. INC (DEC)
directly increments (decrements) the PLL-feedback divider M
and immediately changes the PLL frequency by the smallest
step G (see Table 7 for the frequency granularity G). The INC
and DEC commands are designed for multiple and rapid PLL
frequency changes as required in frequency margining
applications. INC and DEC do not require the user to update
the PLL dividers by the LOAD command, INC and DEC do
not update the PLL_L and PLL_H registers either (use LOAD
for an initial PLL divider setting and, if desired, use GET to
read the PLL configuration). Note that the synthesizer does
not check any boundary conditions such as the VCO
frequency range. Applying the INC and DEC commands
could result in invalid VCO frequencies (VCO frequency
beyond lock range).
Register Maps
Note that the LOAD command is required to update the
PLL dividers by the content of both PLL_L and PLL_H
registers.
Register 0xF0 (CMD) is a write-only command register.
The purpose of CMD is to provide a fast way to increase or
decrease the PLL frequency and to update the registers. The
register accepts four commands, INC (increment M), DEC
(decrement M), LOAD and GET (update registers). It is
recommended to write the INC, DEC commands only after a
valid PLL configuration is achieved. INC and DEC only affect
the M-divider of the PLL (PLL feedback). Applying INC and
DEC commands can result in a PLL configuration beyond the
specified lock range and the PLL may loose lock. The
MPC92432 does not verify the validity of any commands
such as LOAD, INC, and DEC. The INC and DEC commands
change the PLL feedback divider without updating PLL_L
and PLL_H.
Table 16. CMD (0xF0): PLL Command (Write-Only)
Command
Op-Code
INC
xxxx0001b
(0x01)
Increase internal PLL frequency
M:=M+1
DEC
xxxx0010b
(0x02)
Decrease internal PLL frequency
M:=M-1
LOAD
xxxx0100b
(0x04)
Update the PLL divider config.
PLL divider M, N, P:=PLL_L, PLL_H
GET
xxxx1000b
(0x08)
Update the configuration registers
PLL_L, PLL_H:=PLL divider M, N, P
Table 13. Configuration Registers
Address
Name
Content
Access
0x00
PLL_L
Least significant 8 bits of M
R/W
0x01
PLL_H
Most significant 2 bits of M, P, NA,
NB, and lock state
R/W
0xF0
CMD
Command register (write only)
W only
Description
Bit
7
6
5
4
3
2
1
0
I2C — Register Access in Parallel Mode
The MPC92432 supports the configuration of the
synthesizer through the parallel interlace (PLOAD = 0) and
serial interface (PLOAD = 1). Register contents and the
divider configurations are not changed when the user
switches from parallel mode to serial mode. However, when
switching from serial mode to parallel mode, the PLL dividers
immediately reflect the logical state of the hardware pins
M[9:0], NA[2:0], NB, and P.
Applications using the parallel interface to obtain a PLL
configuration can use the serial interface to verify the divider
settings. In parallel mode (PLOAD = 0), the MPC92432
allows read-access to PLL_L and PLL_H through I2C (if
PLOAD = 0, the current PLL configuration is stored in PLL_L,
PLL_H. The GET command is not necessary and also not
supported in parallel mode). After changing from parallel to
serial mode (PLOAD = 1), the last PLL configuration is still
stored in PLL_L, PLL_H. The user now has full write and read
access to both configuration registers through the I2C bus
and can change the configuration at any time.
Name
M9
M8
NA2
NA1
NA0
NB
P
LOCK
Table 17. PLL Configuration in Parallel and Serial Modes
Register 0x00 (PLL_L) contains the least significant bits of
the PLL feedback divider M.
Table 14. PLL_L (0x00, R/W) Register
Bit
7
6
5
4
3
2
1
0
Name
M7
M6
M5
M4
M3
M2
M1
M0
Register content:
M[7:0]
PLL feedback-divider M, bits 7–0
Register 0x01 (PLL_H) contains the two most significant
bits of the PLL feedback divider M, four bits to control the PLL
post-dividers N and the PLL pre-divider P. The bit 0 in PLL_H
register indicates the lock condition of the PLL and is set by
the synthesizer automatically. The LOCK state is a copy of
the PLL lock signal output (LOCK). A write-access to LOCK
has no effect.
Table 15. PLL_H (0x01, R/W) Register
PLL
Configuration
Register content:
M[9:8]
PLL feedback-divider M, bits 9–8
M[9:0]
NA[2:0]
PLL post-divider NA, see Table 9
Parallel
Serial (Registers
PLL_L, PLL_H)
Set pins M9–M0
M[9:0] (R/W)
NA[2:0]
Set pins NA2...NA0
NA[2:0] (R/W)
PLL post-divider NB, see Table 10
NB
Set pin NB
NB (R/W)
P
PLL pre-divider P, see Table 8
P
Set pin P
P (R/W)
LOCK
Copy of LOCK output signal (read-only)
LOCK status
LOCK pin 26
LOCK (Read only)
NB
MPC92432
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MPC92432
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Programming the I2C Interface
set by the user to avoid address conflicts of multiple
MPC92432 devices on the same I2C bus.
Table 18. I2C Slave Address
Bit
7
6
5
4
3
2
1
0
Value
1
0
1
1
0
Pin
ADR1
Pin
ADR0
R/W
Write Mode (R/W = 0)
The configuration registers are written by the bus
controller by the initiation of a write transfer with the
MPC92432 slave address (first byte), followed by the address
of the configuration register (second byte: 0x00, 0x01 or
0xF0), and the configuration data byte (third byte). This
transfer may be followed by writing more registers by sending
the configuration register address followed by one data byte.
Each byte sent by the bus controller is acknowledged by the
MPC92432. The transfer ends by a stop bit sent by the bus
controller. The number of configuration data bytes and the
write sequence are not restricted.
The 7-bit I2C slave address of the MPC92432 synthesizer
is a combination of a 5-bit fixed addresses and two variable
bits which are set by the hardware pins ADR[1:0]. Bit 0 of the
MPC92432 slave address is used by the bus controller to
select either the read or write mode. ’0’ indicates a
transmission (I2C-WRITE) to the MPC92432. ’1’ indicates a
request for data (I2C-READ) from the synthesizer. The
hardware pins ADR1 and ADR0 and should be individually
Table 19. Complete Configuration Register Write Transfer
1 bit
7 bits
1 bit
1 bit
8 bits
1 bit
8 bits
1 bit
8 bits
1 bit
8 bits
1 bit
1 bit
Start
Slave address
R/W
ACK
&PLL_H
ACK
Config-Byte 1
ACK
&PLL_L
ACK
Config-Byte 2
ACK
Stop
10110xx(1)
0
Slave
Mast
Master
1.
Master
0x01
Mast Slave
Master
Data
Slave
0x00
Master
Slave
Master
Data
Slave
Master
xx = state of ADR1, ADR0 pins
Read Mode (R/W = 1)
The configuration registers are read by the bus controller
by the initiation of a read transfer. The MPC92432 supports
read transfers immediately after the first byte without a
change in the transfer direction. Immediately after the bus
controller sends the slave address, the MPC92432
acknowledges and then sends both configuration register
PLL_L and PLL_H (back-to-back) to the bus controller. The
CMD register cannot be read. In order to read the two
synthesizer registers and the current PLL configuration
setting, the user can 1) read PLL_L, PLL_H, write the GET
command (loads the current configuration into PLL_L,
PLL_H) and read PLL_L, PLL_H again. Note that the PLL_L,
PLL_H registers and divider settings may not be equivalent
after the following cases:
a.
Writing the INC command
b.
Writing the DEC command
c.
Writing PLL_L, PLL_H registers with a new
configuration and not writing the LOAD command.
Table 20. Configuration Register Read Transfer
1 bit
7 bits
Start
Slave address
(1)
10110xx
Master
1.
Master
1 bit
1 bit
8 bits
1 bit
8 bits
1 bit
1 bit
R/W
ACK
PLL_L
ACK
PLL_H
ACK
Stop
Master
Slave
1
Mast
Data
Slave
Slave
Data
Mast
Slave
xx = state of ADR1, ADR0 pins
Device Startup
General Device Configuration
It is recommended to reset the MPC92432 during or
immediately after the system powers up (MR = 0). The device
acquires an initial PLL divider configuration through the
parallel interface pins M[9:0], NA[2:0], N, and P(1) with the
low-to-high transition of MR(2). PLL frequency lock is
achieved within the specified lock time (tLOCK) and is
indicated by an assertion of the LOCK signal which
completes the startup procedure. It is recommended to
disable the outputs (CLK_STOPx = 0) until PLL lock is
achieved to suppress output frequency transitions. The
output frequency can be reconfigured at any time through
either the parallel or the serial interface.
1. The parallel interface pins M[9:0], NA[2:0], N, and P may be left open (floating). In this case the initial PLL configuration will have the default
setting of M = 500, P = 1, NA[2:0] = 010, NB = 0, resulting in an internal VCO frequency of 2000 MHz (fref = 16 MHz) and an output frequency
of 250 MHz.
2. The initial PLL configuration is independent on the selected programming mode (PLOAD low or high)
IDT™ 1360 MHz Dual Output LVPECL Clock Synthesizer
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MPC92432
MPC92432
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1360 MHz Dual Output LVPECL Clock Synthesizer
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Note that a PLL configuration obtained by the parallel
interface can be read through I2C independent on the current
programming mode (parallel or serial). Refer to I2C —
Register Access in Parallel Mode for additional information
on how to read a PLL startup configuration through the I2C
interface.
re-programmed to the final VCO frequency at any time
through the serial interface. After the PLL achieved lock at the
desired VCO frequency, enable the outputs by setting
CLK_STOPx = H. PLL lock and re-lock (after any
configuration change through M or P) is indicated by LOCK
being asserted.
Starting-Up Using the Parallel Interface
The simplest way to use the MPC92432 is through the
parallel interface. The serial interface pins (SDA, SDL, and
ADDR[1:0]) can be left open and PLOAD is set to logic low.
After the release of MR and at any other time the PLL/output
frequency configuration is directly set to through the M[9:0],
NA[2:0], NB, and P pins.
LOCK Detect
The LOCK detect circuitry indicates the frequency-lock
status of the PLL by setting and resetting the pin LOCK and
register bit LOCK simultaneously. The LOCK status is
asserted after the PLL acquired frequency lock during the
startup and is immediately deasserted when the PLL lost
lock, for instance when the reference clock is removed. The
PLL may also loose lock when the PLL feedback-divider M or
pre-divider P is changed or the DEC/INC command is issued.
The PLL may not loose lock as a result of slow reference
frequency changes. In any case of loosing LOCK, the PLL
attempts to re-lock to the reference frequency. LOCK and relock of the PLL is indicated by the LOCK signal after a delay
of TBD cycles to prevent signaling temporary PLL locks
during frequency transitions.
Start-Up Using the Serial (I2C) Interface
VCC
MR
Stable & Valid
P, M, N
PLOAD
Selects I2C
Acquiring Lock
LOCK
PLL Lock
CLK_STOPx
Disabled (Low)
QA, QB
tPLH
Active
Figure 4. Start-Up Using I2C Interface
Set PLOAD = 1, CLK_STOPx = L and leave the parallel
interface pins (M[9:0], NA[2:0], N, and P) open. The PLL
dividers are configured by the default configuration at the lowto-high transition of MR. This initial PLL configuration can be
CLK_STOPx
Output Clock Stop
Asserting CLK_STOPx will stop the respective output
clock in logic low state. The CLK_STOPx control is internally
synchronized to the output clock signal, therefore, enabling
and disabling outputs does not produce runt pulses. See
Figure 5. The clock stop controls of the QA and QB outputs
are independent on each other. If the QB runs at half of the
QA output frequency and both outputs are enabled at the
same time, the first clock pulse of QA may not appear at the
same time of the first QB output. (See Figure 6.) Concident
rising edges of QA and QB stay synchronous after the
assertion and de-assertion of the CLK_STOPx controls.
Asserting MR always resets the output divider to a logic low
output state, with the risk of producing an output runt pulse.
(Disable)
(Enable)
(Enable)
Qx
tP_EN
tP_DIS
Figure 5. Clock Stop Timing for NB = 0 (fQA = fQB)
CLK_STOPA,B
(Disable)
(Enable)
(Enable)
QA
QB
Figure 6. Clock Stop Timing for NB = 1 (fQA = 2 fQB)
MPC92432
IDT™ 1360
MHz Dual Output LVPECL Clock Synthesizer
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MPC92432
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Frequency Operating Range
Table 21. MPC92432 Frequency Operating Range for P = 2
fVCO [MHz] (Parameter: fREF in MHz)
M
M[9:0]
170
15
Output Frequency for fXTAL = 16 MHz (Parameter N)
16
18
20
2
4
8
16
32
64
0010101010
1360
1530
1700
680
340
170
85
42.50
21.25
180
0010110100
1440
1620
1800
720
360
180
90
45.00
22.50
190
0010111110
1425
1520
1710
1900
760
380
190
95
47.50
23.75
200
0011001000
1500
1600
1800
2000
800
400
200
100
50.00
25.00
210
0011010010
1575
1680
1890
2100
840
420
210
105
52.50
26.25
220
0011011100
1650
1760
1980
2200
880
440
220
110
55.00
27.50
230
0011100110
1725
1840
2070
2300
920
460
230
115
57.50
28.75
240
0011110000
1800
1920
2160
2400
960
480
240
120
60.00
30.00
250
0011111010
1875
2000
2250
2500
1000
500
250
125
62.50
31.25
260
0100000100
1950
2080
2340
2600
1040
520
260
130
65.00
32.50
270
0100001110
2025
2160
2430
2700
1080
540
270
135
67.50
33.75
280
0100011000
2100
2240
2520
1120
560
280
140
70.00
35.00
290
0100100010
2175
2320
2610
1160
580
290
145
72.50
36.25
300
0100101100
2250
2400
2700
1200
600
300
150
75.00
37.50
310
0100110110
2325
2480
1240
620
310
155
77.50
38.75
320
0101000000
2400
2560
1280
640
320
160
80.00
40.00
330
0101001010
2475
2640
1320
660
330
165
82.50
41.25
340
0101010100
2550
2720
1360
680
340
170
85.00
42.50
IDT™ 1360 MHz Dual Output LVPECL Clock Synthesizer
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MPC92432
MPC92432
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MPC92432
1360 MHz Dual Output LVPECL Clock Synthesizer
NETCOM
Table 22. MPC92432 Frequency Operating Range for P = 4
fVCO [MHz] (Parameter: fREF in MHz)
15
Output Frequency for fXTAL = 16 MHz (Parameter N)
M
M[9:0]
16
18
20
2
4
8
16
32
64
340
0101010100
1360
1530
1700
680
340
170
85.0
42.50
21.25
350
0101011110
1400
1575
1750
700
350
175
87.5
43.75
21.875
360
0101101000
1440
1620
1800
720
360
180
90.0
45.00
22.50
370
0101110010
1480
1665
1850
740
370
185
92.5
46.25
23.125
1387.5
380
0101111100
1425.0
1520
1710
1900
760
380
190
95.0
47.50
23.75
390
0110000110
1462.5
1560
1755
1950
780
390
195
97.5
48.75
24.375
400
0110010000
1500.0
1600
1800
2000
800
400
200
100.0
50.00
25.00
410
0110110010
1537.5
1640
1845
2050
820
410
205
102.5
51.25
25.625
420
0110100100
1575.0
1680
1890
2100
840
420
210
105.0
52.50
26.25
430
0110101110
1612.5
1720
1935
2150
860
430
215
107.5
53.75
26.875
440
0110111000
1650.0
1760
1980
2200
880
440
220
110.0
55.00
27.50
450
0111000010
1687.5
1800
2025
2250
900
450
225
112.5
56.25
28.125
460
0111001100
1725.0
1840
2070
2300
920
460
230
115.0
57.50
28.75
470
0111010110
1762.5
1880
2115
2350
940
470
235
117.5
58.75
29.375
480
0111100000
1800.0
1920
2160
2400
960
480
240
120.0
60.00
30.00
490
0111101010
1837.5
1960
2205
2450
980
490
245
122.5
61.25
30.626
500
0111110100
1875.0
2000
2250
2500
1000
500
250
125.0
62.50
31.25
510
0111111110
1912.5
2040
2295
2550
1020
510
255
127.5
63.75
31.875
520
1000001000
1950.0
2080
2340
2600
1040
520
260
130.0
65.00
32.50
530
1000010010
1987.5
2120
2475
2650
1060
530
265
132.5
66.25
33.125
540
1000011100
2025.0
2160
2520
2700
1080
540
270
135.0
67.50
33.75
550
1000100110
2062.5
2200
2565
1100
550
285
137.5
68.75
34.375
560
1000110000
2100.0
2240
2610
1120
560
280
140.0
70.00
35.00
570
1000111010
2137.5
2280
2700
1140
570
285
142.5
71.25
35.625
580
1001000100
2175.0
2320
1160
580
290
145.0
72.50
36.25
590
1001001110
2212.5
2360
1180
590
295
147.5
73.75
36.875
600
1001011000
2250.0
2400
1200
600
300
150.0
75.00
37.50
610
1001100010
2287.5
2440
1220
610
305
152.5
76.25
38.125
620
1001101100
2325.0
2480
1240
620
310
155.0
77.50
38.75
630
1001110110
2362.5
2520
1260
630
315
157.5
78.75^
39.375
640
1010000000
2400.0
2560
1280
640
320
160.0
80.00
40.00
650
1010001010
2437.5
2600
1300
650
325
162.5
81.25
40.625
660
0010010100
2475.0
2640
1320
660
330
165
82.5
41.25
670
1010011110
2512.5
2680
1340
670
335
167.5
83.75
41.875
680
1010101000
2550.0
2720
1360
680
340
170
85.00
42.50
MPC92432
IDT™ 1360
MHz Dual Output LVPECL Clock Synthesizer
Freescale Timing Solutions Organization has been acquired by Integrated Device Technology, Inc
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MPC92432
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MPC92432
1360 MHz Dual Output LVPECL Clock Synthesizer
VCC_PLL Filter
The MPC92432 is a mixed analog/digital product. Its
analog circuitry is naturally susceptible to random noise,
especially if this noise is seen on the power supply pins.
Random noise on the VCC_PLL pin impacts the device AC
characteristics. The MPC92432 provides separate power
supplies for the digital circuitry (VCC) and the internal PLL
(VCC_PLL) of the device. The purpose of this design
technique is to isolate the high switching noise digital outputs
from the relatively sensitive internal analog phase-locked
loop. In digital system environments where it is more difficult
to minimize noise on the power supplies a second level of
isolation is recommended: a power supply filter on the
VCC_PLL pin for the MPC92432.
VCC
RF = 10–15 Ω
CF = 22 µF
VCC_PLL
10 nF
MPC92432
VCC
7
33...100 nF
Figure 7. VCC_PLL Power Supply Filter
Figure 7 illustrates a recommended power supply filter
scheme.
The MPC92432 is most susceptible to noise with spectral
content in the 100 kHz to 1 MHz range. Therefore, the filter
should be designed to target this range. The key parameter
that needs to be met in the final filter design is the DC voltage
drop that will be seen between the VCC supply and the
VCC_PLL pin of the MPC92432. From the data sheet, the
VCC_PLL current (the current sourced through the VCC_PLL
pin) is maximum 10 mA, assuming that a minimum of 2.985 V
must be maintained on the VCC_PLL pin. The resistor shown
in Figure 7 must have a resistance of 10–15 Ω to meet the
voltage drop criteria. The minimum values for RF and the filter
capacitor CF are defined by the filter characteristics: the RC
filter should provide an attenuation greater than 40 dB for
NETCOM
noise whose spectral content is above 100 kHz. In the
recommended filter shown in Figure 7 the filter cut-off
frequency is around 3.0–4.5 kHz and the noise attenuation at
100 kHz is better than 42 dB.
As the noise frequency crosses the series resonant point
of an individual capacitor its overall impedance begins to look
inductive and thus increases with increasing frequency. The
parallel capacitor combination shown ensures that a low
impedance path to ground exists for frequencies well above
the bandwidth of the PLL.
The On-Chip Crystal Oscillator
The MPC92432 features an integrated on-chip crystal
oscillator to minimize system implementation cost. The
integrated oscillator is a Pierce-type that uses the crystal in
its parallel resonance mode. It is recommended to use a 15
to 20 MHz crystal with a load specification of CL = 10 pF.
Crystals with a load specification of CL = 20 pF may be used
at the expense of an resulting slightly higher frequency than
specified for the crystal. Externally connected capacitors on
both the XTAL_IN and XTAL_OUT pins are not required but
can be used to fine-tune the crystal frequency as desired.
The crystal, the trace and optional capacitors should be
placed on the board as close as possible to the MPC92432
XTAL_IN and XTAL_OUT pins to reduce crosstalk of active
signals into the oscillator. Short and wide traces further
reduce parasitic inductance and resistance. It is further
recommended to guard the crystal circuit by placing a ground
ring around the traces and oscillator components.
Table 23. Recommended Crystal Specifications
Parameter
Value
Crystal Cut
Fundamental AT Cut
Resonance Mode
Parallel
Crystal Frequency
16–20 MHz
Shunt Capacitance C0
5–7 pF
Load Capacitance CL
10 pF
Equivalent Series Resistance ESR
20–60 Ω
IDT™ 1360 MHz Dual Output LVPECL Clock Synthesizer
Advanced
Clock Drivers
Devices has been acquired by Integrated Device Technology, Inc
Freescale
Timing Solutions
Organization
Freescale Semiconductor
15
MPC92432
MPC92432
15
MPC92432
1360 MHz Dual Output LVPECL Clock Synthesizer
NETCOM
Jitter Performance of the MPC92432
Figure 8 and Figure 9 illustrate the RMS jitter performance
of the MPC92432 across its specified VCO frequency range.
The cycle-to-cycle and period jitter is a function of the VCO
frequency and the output divider N. The general trend is that
as the output frequency increases (higher VCO frequency
and lower N-divider) the MPC92432 output jitter decreases.
Optimum jitter performance can be achieved at higher VCO
and output frequencies. The maximum cycle-to-cycle and
period jitter published in Table 6 (AC characteristics)
correspond to the jitter performance at the lowest VCO
frequency limit. The VCO frequency can be calculated using
formula (2).
AC Test Reference and Output Termination
The MPC92432 LVPECL outputs are designed to drive
50 transmission lines and require a DC termination to
VTT = VCC – 2 V. Figure 10 illustrates the AC test reference
for the MPC92432 as used in characterization and test of this
circuit. If a separate termination voltage (VTT) is not available,
applications may use alternative output termination methods
such as shown in Figure 11 and Figure 12.
The high-speed differential output signals of the
MPC92432 are incompatible to single-ended LVCMOS
signals. In order to use the synthesizer in LVCMOS clock
signal environments, the dual-channel translator device
MC100ES60T23 provides the necessary level conversion.
The MC100ES60T23 has been specifically designed to
interface with the MPC92432 and supports clock frequency
up to 180 MHz.
Figure 8. MPC92432 Cycle-to-Cycle Jitter
Figure 9. MPC92432 Period Jitter
.
Pulse
Generator
Z = 50 Ω
fREF = 16 MHz
QA
Z = 50 Ω
QB
Z = 50 Ω
Z = 50 Ω
Synthesizer
RT = 50 Ω
DUT MPC92432
RT = 50 Ω
VTT
Figure 10. MPC92432 AC Test Reference
MPC92432
IDT™ 1360
MHz Dual Output LVPECL Clock Synthesizer
Freescale Timing Solutions Organization has been acquired by Integrated Device Technology, Inc
16
16
MPC92432
Advanced Clock Drivers Devices
Freescale Semiconductor
MPC92432
1360 MHz Dual Output LVPECL Clock Synthesizer
NETCOM
VCC
Qx
130 Ω
Qx
Z = 50 Ω
Z = 50 Ω
MPC92432
MPC92432
50 Ω
50 Ω
82 Ω
SMD Resistor Network
Figure 11. Thevenin Termination
46.4 Ω
Figure 12. Resistor Network Termination
VTT
50 Ω
QA
Z = 50 Ω
QB
Z = 50 Ω
MPC92432
VTT
MC100ES60T23
Figure 13. Interfacing with LVCMOS Logic for Frequency < 180 MHz
IDT™ 1360 MHz Dual Output LVPECL Clock Synthesizer
Advanced
Clock Drivers
Devices has been acquired by Integrated Device Technology, Inc
Freescale
Timing Solutions
Organization
Freescale Semiconductor
17
MPC92432
MPC92432
17
MPC92432
1360 MHz Dual Output LVPECL Clock Synthesizer
NETCOM
PACKAGE DIMENSIONS
4X
NOTES:
1. DIMENSIONING AND TOLERANCING PER ASME
Y14.5m, 1994.
2. CONTROLLING DIMENSION: MILLIMETER.
3. DATUM PLAN AB IS LOCATED AT BOTTOM OF
LEAD AND IS COINCIDENT WITH THE LEAD
WHERE THE LEAD EXITS THE PLASTIC BODY AT
THE BOTTOM OF THE PARTING LINE.
4. DATUMS T, U, AND Z TO BE DETERMINED AT
DATAUM PLANE AB.
5. DIMENSIONS S AND V TO BE DETERMINED AT
SEATING PLANE AC.
6. DIMENSIONS A AND B DO NOT INCLUDE MOLD
PROTRUSION. ALLOWABLE PROTRUSION IS
0.250 PER SIDE. DIMENSIONS A AND B DO
INCLUDE MOLD MISMATCH AND ARE
DETERMINED AT DATUM PLANE AB.
7. DIMENSION D DOES NOT INCLUDE DAMBAR
PROTRUSION. DAMBAR PROTRUSION SHALL
AE
NOT CAUSE THE D DIMENSION TO EXCEED
0.350.
8. MINIMUM SOLDER PLATE THICKNESS SHALL BE
0.0076.
9. EXACT SHAPE OF EACH CORNER IS OPTIONAL.
0.200 AB T-U Z
9
DETAIL Y
A
P
A1
48
37
36
1
T
U
B
V
AE
B1
12
25
13
V1
24
DIM
A
A1
B
B1
C
D
E
F
G
H
J
K
L
M
N
P
R
S
S1
V
V1
W
AA
Z
S1
T, U, Z
S
DETAIL Y
4X
0.200 AC T-U Z
0.080 AC
G
AB
AD
AC
MILLIMETERS
MIN
MAX
7.000 BSC
3.500 BSC
7.000 BSC
3.500 BSC
1.400
1.600
0.170
0.270
1.350
1.450
0.170
0.230
0.500 BSC
0.050
0.150
0.090
0.200
0.500
0.700
0˚
7˚
12˚ REF
0.090
0.160
0.250 BSC
0.150
0.250
9.000 BSC
4.500 BSC
9.000 BSC
4.500 BSC
0.200 REF
1.000 REF
M˚
BASE METAL
TOP & BOTTOM
J
0.250
N
C
E
GAUGE PLANE
R
F
D
0.080
M
AC T-U Z
SECTION AE-AE
H
W
L˚
K
DETAIL AD
AA
CASE 932-03
ISSUE F
48-LEAD LQFP PACKAGE
MPC92432
IDT™ 1360
MHz Dual Output LVPECL Clock Synthesizer
Freescale Timing Solutions Organization has been acquired by Integrated Device Technology, Inc
18
18
MPC92432
Advanced Clock Drivers Devices
Freescale Semiconductor
MPC92432
MPC92459
PART NUMBERS
900
1360
MHz
MHz
Low
DualVoltage
Output
LVDS
LVPECL
Clock
Clock
Synthesizer
Synthesizer
INSERT
PRODUCT
NAME
AND
DOCUMENT
TITLE
NETCOM
NETCOM
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